IFE, EH & RW

1. IFE, EH & RW

2. International Fisher Effect (IFE) • IFE builds on the law of one price, but for financial transactions. • Idea: The return to international investors who invest in money markets in their home country should be equal to the return they would get if they invest in foreign money markets once adjusted for currency fluctuations. • Exchange rates will be set in such a way that international investors cannot profit from interest rate differentials --i.e., no profits from carry trades.

3. The "effective" T-day return on a foreign bank deposit is: rd (f) = (1 + if x T/360) (1 + sT) -1. • While, the effective T-day return on a home bank deposit is: rd (d) = id x T/360. • Setting rd (d) = rd (f) and solving for sT = (St+T/St - 1) we get: sIFET = (1 + id x T/360) - 1. (This is the IFE) (1 + if x T/360) • Using a linear approximation: sIFET  (id - if) x T/360. • sIFET represents an expectation. It’s the expected change in St from t to t+T that makes looking for the “extra yield” in international money markets not profitable.

4. • Since IFE gives us an expectation for a future exchange rate –St+T-, if we believe in IFE we can use this expectation as a forecast. Example: Forecasting St using IFE. It’s 2011:I. You have the following information: S2011:I=1.0659 USD/EUR. iUSD,2011:I=6.5% iEUR,2011:I=5.0%. T = 1 quarter = 90 days. eIFEf,,2011:II = [1+ iUSD,2011:I x (T/360)]/[1+ iEUR,2011:I x (T/360)] - 1 = = [1+.065*(90/360))/[1+.05*(90/360)] – 1 = 0.003704 E[S2011:II] = S2011:I x (1+eIFEf,,2011:II ) = 1.659 USD/EUR *(1 + .003704) = 1.06985 USD/EUR That is, next quarter, you expect St to change 1.06985 USD/EUR to compensate for the higher US interest rates. ¶

5. Note: Like PPP, IFE also gives an equilibrium exchange rate. Equilibrium will be reached when there is no capital flows from one country to another to take advantage of interest rate differentials. IFE: Implications If IFE holds, the expected cost of borrowing funds is identical across currencies. Also, the expected return of lending is identical across currencies. Carry trades –i.e., borrowing a low interest currency to invest in a high interest currency- should not be profitable. If departures from IFE are consistent, investors can profit from them.

6. Example: Mexican peso depreciated 5% a year during the early 90s. Annual interest rate differential (iMEX - iUSD) were between 7% and 16%. The E[st]= -5% > sIFEt => Pseudo-arbitrage is possible (The MXN at t+T is overvalued!) Carry Trade Strategy: 1) Borrow USD funds (at iUSD) 2) Convert to MXN at St 3) Invest in Mexican funds (at iMEX) 4)Wait until T. Then, convert back to USD at St+T. Expected foreign exchange loss 5% (E[st ]= -5%) Assume (iUSD – iMXN) = -7%. (Say, iUSD= 5%, iMXN=12%.) E[st ]= -5% > sIFEt=-7% => “on average” strategy (1)-(4) should work.

7. Example (continuation): Expected return (MXN investment): rd (f) = (1 + iMXNxT/360)(1 + sT) -1 = (1.12)*(1-.05) - 1 = 0.064 Payment for USD borrowing: rd (d) = id x T/360 = .05 Expected Profit = .014 per year • Overall expected profits ranged from: 1.4% to 11%. Note: Fidelity used this uncovered strategy during the early 90s. In Dec. 94, after the Tequila devaluation of the MXN against the USD, lost everything it gained before. Not surprised, after all the strategy is a “pseudo-arbitrage” strategy! ¶

8. You may have noticed that IFE pseudo-arbitrage strategy differs from covered arbitrage in the final step. Step 4) involves no coverage. • It’s an uncovered strategy. IFE is also called Uncovered Interest Rate Parity (UIRP).

9. 1. Visual evidence. Based on linearized IFE: sT (id - if) x T/360 Expect a 45 degree line in a plot of sT against (id-if) Example: Plot for the monthly USD/EUR exchange rate (1999-2007) No 45° line => Visual evidence rejects IFE. ¶

10. 2. Regression evidence st = (St+T - St)/St = α + β (id - if )t + εt, (εt error term, E[εt]=0). • The null hypothesis is: H0 (IFE true): α=0 and β=1 H0 (IFE not true): α≠0 and/or β≠1 Example: Testing IFE for the USD/EUR with monthly data (99-07). R2 = 0.057219 Standard Error = 0.016466 F-statistic (slopes=0) = 6.311954 (p-value=0.0135) F-test (α=0 and β=1) = 76.94379 (p-value= lower than 0.0001) => rejects H0 at the 5% level (F2,104,.05=3.09) Observations = 106

11. Let’s test H0, using t-tets (t104,.05 = 1.96) : tα=0 (t-test for α = 0): (0.00293 – 0)/0.001722 = 1.721 => cannot reject at the 5% level. tβ=1 (t-test for β = 1): (-0.26342-1)/0.10485 = -12.049785 => reject at the 5% level. Formally, IFE is rejected in the short-run (both the joint test and the t-test reject H0). Also, note that β is negative, not positive as IFE expects. ¶ • IFE: Evidence Similar to PPP, no short-run evidence. Some long-run support: => Currencies with high interest rate differential tend to depreciate. (For example, the Mexican peso finally depreciated in Dec. 1994.)

12. Expectations Hypothesis (EH) • According to the Expectations hypothesis (EH) of exchange rates: Et[St+T] = Ft,T. That is, on average, the future spot rate is equal to the forward rate. Since expectations are involved, many times the equality will not hold. It will only hold on average.

13. Example: Suppose that over time, investors violate EH. Data: Ft,180 = 5.17 ZAR/USD. An investor expects: E[St+180]=5.34 ZAR/USD. (A potential profit!) Strategy for the non-EH investor: 1. Buy USD forward at ZAR 5.17 2. In 180 days, sell the USD for ZAR 5.34. Now, suppose everybody expects St+180 = 5.34 ZAR/USD => Disequilibrium: everybody buys USD forward (nobody sells USD forward). And in 180 days, everybody will be selling USD. Prices should adjust until EH holds. Since an expectation is involved, sometimes you’ll have a loss, but, on average, you’ll make a profit. ¶

14. Expectations Hypothesis: Evidence Under EH, Et[St+T] = Ft,T → Et[St+T - Ft,T] = 0 Empirical tests of the EH are based on a regression: (St+T - Ft,T)/St = α + β Zt + εt, (where E[εt]=0) where Zt represents any economic variable that might have power to explain St, for example, (id-if). The EH null hypothesis: H0: α=0 and β=0. (Recall (St+T - Ft) should be unpredictable!) Usual result: β < 0 (and significant) when Zt= (id-if). But, the R2 is very low.

15. Expectations Hypothesis: IFE (UIRP) Revisited EH: Et[St+T] = Ft,T. Replace Ft,T by IRP, say, linearized version: Et[St+T] ≈ St [1+(id- if) x T/360]. A little bit of algebra gives: (E[St+T] - St)/St ≈ (id - if) x T/360 <= IFE linearized! • EH can also be tested based on the Uncovered IRP (IFE) formulation: (St+T - St)/St = st = α + β (id - if) + εt. The null hypothesis is H0: α=0 and β=1. Usual Result: β < 0  when (id-if)=2%, the exchange rate appreciates by (β x .02), instead of depreciating by 2% as predicted by UIPT!

16. Summary: Forward rates have little power for forecasting spot rates  Puzzle (the forward bias puzzle)! Explanations of forward bias puzzle: - Risk premium? (holding a risky asset requires compensation) - Errors in calculating Et[St+T]? (It takes time to learn the game) - Peso problem? (small sample problem)

17. Risk Premium The risk premium of a given security is defined as the return on this security, over and above the risk-free return. • Q: Is a risk premium justified in the FX market? A: Only if exchange rate risk is not diversifiable. After some simple algebra, we find that the expected excess return on the FX market is given by: (Et[St+T] - Ft,T)/St = Pt,t+T. A risk premium, P, in FX markets implies Et[St+T] = Ft,T + St Pt,t+T. If Pt,t+T is consistently different from zero, markets will display a forward bias.

18. Example: Understanding the meaning of the FX Risk Premium. Data: St = 1.58 USD/GBP Et[St+6-mo] = 1.60 USD/GBP Ft,6-mo= 1.62 USD/GBP. • Expected change in St => (Et[St+6-mo]-St)/St =(1.60-1.58)/1.58= 0.0127. • 6-mo FX premium  (Ft,6-mo-St)/St=(1.62-1.58)/1.58= 0.0253. • In the next 6-month period: The GBP is expected to appreciate against the USD by 1.27% The forward premium suggests a GBP appreciation of 2.53%.

19. • In the next 6-month period: The GBP is expected to appreciate against the USD by 1.27% The forward premium suggests a GBP appreciation of 2.53%. • Discrepancy: The presence of a FX risk premium, Pt,t+6-mo, which makes the forward rate a biased predictor of St+6-mo. • The expected (USD) return from holding a GBP deposit will be more than the USD return from holding a USD deposit. • Rational Investor: The higher return from holding a GBP deposit is necessary to induce investors to hold the riskier GBP denominated investments. ¶

20. Martingale-RW Model The Martingale-Random Walk Model A random walk is a time series independent of its own history. Your last step has no influence in your next step. The past does not help to explain the future. Motivation: Drunk walking in a park. (Problem posted in Nature. Solved by Karl Pearson. July 1905 issue.) Intuitive notion: The FX market is a "fair game.“ (Unpredictable!)

21. • Martingale-Random Walk Model: Implications The Random Walk Model (RWM) implies: Et[St+T] = St. Powerful theory: at time t, all the info about St+T is summarized by St. Theoretical Justification: Efficient Markets (all available info is incorporated into today’s St.) Example: Forecasting with RWM St = 1.60 USD/GBP Et[St+7-day] = 1.60 USD/GBP Et[St+180-day] = 1.60 USD/GBP Et[St+10-year] = 1.60 USD/GBP. ¶ Note: If St follows a random walk, a firm should not spend any resources to forecast St+T.

22. • Martingale-Random Walk Model: Evidence Meese and Rogoff (1983, Journal of International Economics) tested the short-term forecasting performance of different models for the four most traded exchange rates. They considered economic models (PPP, IFE, Monetary Approach, etc.) and the RWM. The metric used in the comparison: forecasting error (squared).  The RWM performed as well as any other model. Cheung, Chinn and Pascual (2005) checked the Meese and Rogoff’s results with 20 more years of data.  RWM still the best model.